Holographic shear rheology of viscoelastic fluids

TL;DR

This paper introduces a novel holographic shear rheometry technique using digital holography microscopy and particle tracking velocimetry to measure viscoelastic fluid properties in microchannels, providing detailed 3D flow visualization and rheological data.

Contribution

The study develops a holographic shear rheometry method that accurately measures complex fluid rheology without prior assumptions, validated against simulations and traditional methods.

Findings

Quantitative shear rheology data for Newtonian and PEO solutions over a wide shear rate range.

Holographic method agrees well with CFD simulations and macrorheometry.

Technique effectively quantifies wall-slip and visualizes particle migration.

Abstract

In this study, we report the use of digital holography microscopy (DHM) for 3D-resolved flow kinematics and shear rheometry of viscoelastic polymeric fluids. We computationally reconstruct the recorded holograms to visualize the tracer imbued flow volume in microchannels, followed by implementation of particle tracking velocimetry (PTV) to quantitate spatially-resolved velocity fields in 3D. In order to select optimal parameters for DHM-PTV characterization of complex fluids, we studied the effect of hologram recording distance, seeding density and particle size. Using the optimal parameters, we show quantitative characterization of the shear rheology from the velocity fields without any a-priori assumptions of wall boundary condition or constitutive equation. The viscosity versus shear rate data for Newtonian and polyethylene oxide solutions could be measured in the range of ~ 0.05 - 20,000 s-1 with just four input flow rates. This data from holographic shear rheometry was found to be in good agreement with computational fluid dynamics simulations and macrorheometry. The holographic shear rheology technique remained unaffected by wall-slip events and instead provided an avenue to quantitate slip severity. Finally, we discuss holographic visualization of particle migration in microfluidic flows which can limit flow field access while at the same time provide a fingerprint of the suspending fluid rheology.